On the Nature of Nucleobase Stacking in RNA: A Comprehensive Survey of Its Structural Variability and a Systematic Classification of Associated Interactions

Jhunjhunwala, Ayush; Ali, Zakir; Bhattacharya, Swapan; Halder, Antarip; Mitra, Abhijit; Sharma, Purshotam

doi:10.1021/acs.jcim.0c01225

Cited by 13 publications

(50 citation statements)

References 39 publications

(79 reference statements)

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“…In addition, we visually identified and characterized all types of stacking interactions present in the crystal structure (Figure B) and during simulations (Tables S18–S21) using the “Stack Detector” web portal () . This tool detects stacking interactions using a 5 Å cut off for the center-to-center distance of the nucleobase rings, a 23° cut off for the tilt angle between the nucleobase rings, and 40° for the dihedral angles representing the horizontal displacement of one nucleobase ring with respect to the other, within a stack .…”

Section: Methodsmentioning

confidence: 99%

“…(A) Hydrogen-bonding (base-pairing) interactions represented using the Leontis–Westhof symbols and (B) stacking interactions between the residues deduced from the crystal structure of the aptamer domain of the ykkC -III riboswitch bound to the guanidinium cation ligand (PDB code: 5NWQ) represented using the recently proposed symbols . Specifically, arrows represent different stacking types based on the faces of nucleobases ( ≫ upward, ≪ downward, >< inward, and <> outward).…”

Section: Introductionmentioning

confidence: 99%

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Molecular Dynamics Simulations of the Aptamer Domain of Guanidinium Ion Binding Riboswitch ykkC-III: Structural Insights into the Discrimination of Cognate and Alternate Ligands

Negi

Mahmi

Prabhakar

et al. 2021

J. Chem. Inf. Model.

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Guanidinium ion is a toxic cellular metabolite. The ykkC-III riboswitch, an mRNA stretch, regulates the gene expression by undergoing a conformational change in response to the binding of a free guanidinium ion and thereby plays a potentially important role in alleviating guanidinium toxicity in cells. An experimental crystal structure of the guanidinium-bound aptamer domain of the riboswitch from Thermobifida Fusca revealed the overall RNA architecture and mapped the specific noncovalent interactions that stabilize the ligand within the binding pocket aptamer. However, details of how the aptamer domain discriminates the cognate ligand from its closest structurally analogous physiological metabolites (arginine and urea), and how the binding of cognate ligand arrays information from the aptamer domain to the expression platform for regulating the gene expression, are not well understood. To fill this void, we perform a cumulative of 2 μs all-atom explicit-solvent molecular dynamics (MD) simulations on the full aptamer domain, augmented with quantum-chemical calculations on the ligand-binding pocket, to compare the structural and dynamical details of the guanidinium-bound state with the arginine or urea bound states, as well as the unbound (open) state. Analysis of the ligand-binding pocket reveals that due to unfavorable interactions with the binding-pocket residues, urea cannot bind the aptamer domain and thereby cannot alter the gene expression. Although interaction of the guanidyl moiety of arginine within the binding pocket is either comparable or stronger than the guanidinium ion, additional non-native hydrogen-bonding networks, as well as differences in the dynamical details of the argininebound state, explain why arginine cannot transmit the information from the aptamer domain to the expression platform. Based on our simulations, we propose a mechanism of how the aptamer domain communicates with the expression platform. Overall, our work provides interesting insights into the ligand recognition by a specific class of riboswitches and may hopefully inspire future studies to further understand the gene regulation by riboswitches.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Molecular Dynamics Simulations of the Aptamer Domain of Guanidinium Ion Binding Riboswitch ykkC-III: Structural Insights into the Discrimination of Cognate and Alternate Ligands

Negi

Mahmi

Prabhakar

et al. 2021

J. Chem. Inf. Model.

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“…Base pairing can occur in different orientations based upon which ‘edge’ of the nucleobase is involved in the pairing [ 26 ]. Base stacking contributes to duplex formation as well as the stability of a folded RNA [ 27 , 28 ]. RNA modifications contribute to either enhanced, reduced, or altered base pairing and stacking preferences, conformational flexibility, helical winding, groove hydrophobicity and polarity, and stability of tertiary and long-range interactions [ 1 , 22 , 29 ].…”

Section: Classification Of Modified Rna Nucleosides Based On Their St...mentioning

confidence: 99%

Challenges with Simulating Modified RNA: Insights into Role and Reciprocity of Experimental and Computational Approaches

D'Esposito

Myers

Chen

et al. 2022

Genes

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RNA is critical to a broad spectrum of biological and viral processes. This functional diversity is a result of their dynamic nature; the variety of three-dimensional structures that they can fold into; and a host of post-transcriptional chemical modifications. While there are many experimental techniques to study the structural dynamics of biomolecules, molecular dynamics simulations (MDS) play a significant role in complementing experimental data and providing mechanistic insights. The accuracy of the results obtained from MDS is determined by the underlying physical models i.e., the force-fields, that steer the simulations. Though RNA force-fields have received a lot of attention in the last decade, they still lag compared to their protein counterparts. The chemical diversity imparted by the RNA modifications adds another layer of complexity to an already challenging problem. Insight into the effect of RNA modifications upon RNA folding and dynamics is lacking due to the insufficiency or absence of relevant experimental data. This review provides an overview of the state of MDS of modified RNA, focusing on the challenges in parameterization of RNA modifications as well as insights into relevant reference experiments necessary for their calibration.

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“…Noncovalent interactions are specifically suited for biomolecular recognition. Owing to their importance, a significant number of studies in the last decade have analyzed the distribution of noncovalent interactions involved in biomolecular recognition [4–11] …”

Section: Introductionmentioning

confidence: 99%

“…Owing to their importance, a significant number of studies in the last decade have analyzed the distribution of noncovalent interactions involved in biomolecular recognition. [4][5][6][7][8][9][10][11] RNA : protein recognition is a specific type of biomolecular recognition that encompasses a wide variety of processes, [12] such as ribosomal function (e. g., interaction of ribosomal protein factors with rRNA), [13] transcription (i. e., interaction of RNA polymerases with mRNA), [14] tRNA loading (i. e., interaction of tRNA with aminoacyl tRNA synthetases), [15] and the interaction of proteins with ribonucleotide (rN) cofactors for their catalytic function. [9] Thus, not surprisingly, significant literature has been devoted towards assessment of the distribution of noncovalent interactions in RNA : protein complexes.…”

Section: Introductionmentioning

confidence: 99%

Exploring the Nature of Hydrogen Bonding between RNA and Proteins: A Comprehensive Analysis of RNA : Protein Complexes

2021

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A nonredundant dataset of ∼300 high (up to 2.5 Å) resolution X‐ray structures of RNA : protein complexes were analyzed for hydrogen bonds between amino‐acid residues and canonical ribonucleotides (rNs). The identified 17100 contacts were classified based on the identity (rA, rC, rG or rU) and interacting fragment (base, sugar, or ribose) of the rN, the nature (polar or nonpolar) and interacting moiety (main chain or side chain) of the amino‐acid residue, as well as the rN and amino‐acid atoms participating in the hydrogen bonding. 80 possible hydrogen‐bonding combinations (4 (rNs)×20 (amino acids)) involve a wide variety of RNA and protein types and are present in multiple occurrences in almost all PDB files. Comparison with the analogously‐selected DNA:protein complexes reveals that the absence of 2′‐OH group in DNA mainly accounts for the differences in DNA:protein and RNA : protein hydrogen bonding. Search for intrinsically‐stable base:amino acid pairs containing single or multiple hydrogen bonds reveals 37 unique pairs, which may act as well‐defined RNA : protein interaction motifs. Overall, our work collectively analyzes the largest set of nucleic acid‐protein hydrogen bonds to date, and therefore highlights several trends that may help frame structural rules governing the physiochemical characteristics of RNA : protein recognition.

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On the Nature of Nucleobase Stacking in RNA: A Comprehensive Survey of Its Structural Variability and a Systematic Classification of Associated Interactions

Cited by 13 publications

References 39 publications

Molecular Dynamics Simulations of the Aptamer Domain of Guanidinium Ion Binding Riboswitch ykkC-III: Structural Insights into the Discrimination of Cognate and Alternate Ligands

Molecular Dynamics Simulations of the Aptamer Domain of Guanidinium Ion Binding Riboswitch ykkC-III: Structural Insights into the Discrimination of Cognate and Alternate Ligands

Challenges with Simulating Modified RNA: Insights into Role and Reciprocity of Experimental and Computational Approaches

Exploring the Nature of Hydrogen Bonding between RNA and Proteins: A Comprehensive Analysis of RNA : Protein Complexes

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